Use of Magnetic Modulation of Nitrogen-Vacancy Center Fluorescence in Nanodiamonds for Quantitative Analysis of Nanoparticles in Organisms

Abstract: The fluorescence intensity emitted by nitrogen-vacancy (NV) centers in diamond nanoparticles can be readily modulated by the application of a magnetic field using a small electromagnet. By acquiring interleaved images acquired in the presence and absence of the magnetic field and performing digital subtraction, the fluorescence intensity of the NV nanodiamond can be isolated from scattering and autofluorescence even when these backgrounds are changing monotonically during the experiments. This approach has the… Show more

“…Initially, to verify the successful incorporation of diamond nanoparticles into our TPP structures, we construct a widefield ODMR contrast image of a 15 μm diameter, 5 μm tall cylindrical structure, containing 100 nm diamond particles by applying microwaves at 2.87 GHz and subtracting out the background fluorescence (Figure C). This methodology is employed in a variety of other works on NV center sensing. ,− In this image, the intensity of each camera pixel is determined by I contrast = | I mw false( on false) − I mw false( off false) | …”

Complex Three-Dimensional Microscale Structures for Quantum Sensing Applications

“…Initially, to verify the successful incorporation of diamond nanoparticles into our TPP structures, we construct a widefield ODMR contrast image of a 15 μm diameter, 5 μm tall cylindrical structure, containing 100 nm diamond particles by applying microwaves at 2.87 GHz and subtracting out the background fluorescence (Figure C). This methodology is employed in a variety of other works on NV center sensing. ,− In this image, the intensity of each camera pixel is determined by I contrast = | I mw false( on false) − I mw false( off false) | …”

Complex Three-Dimensional Microscale Structures for Quantum Sensing Applications

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